KR20230046389A - How to manufacture bite blocks and STL files using implant round rods. - Google Patents

Abstract

The present invention relates to a system, a method, and a computer program for manufacturing an implant transplanting guide. For the implant transplanting guide manufacturing system, the present invention comprises: a dental terminal which transmits a 3D image of the inside of the oral cavity captured by CT to a management server while a guide tray having impression materials filled therein is inserted into the oral cavity of a subject, and receives a file for processing an implant transplanting guide from the management server; a management server which when receiving the 3D image from the dental terminal, transmits a design request signal to one or more pre-registered planner terminals, and when receiving an implant design information from the planner terminal having the design request signal accepted, generates the file for processing an implant transplanting guide using the same; and a planner terminal which when receiving the design request signal from the management server, transmits a response to whether to accept the design request signal to the management server, and when receiving the 3D image from the management server, receives the implant design information corresponding to the same to transmit the same to the management server. The guide tray contains one or more markers for matching an image of the guide tray with the 3D image and has a tooth shape of the subject impressed. The implant design information contains location information of a guide hole formed on the guide tray. According to the present invention, a manufacturing time of the implant transplanting guide is vastly reduced to have the effect of greatly improving the convenience of the subject.

Description

How to manufacture bite blocks and STL files using implant round rods {How to manufacture bite blocks and STL files using implant round rods.}

The present invention relates to a system, method, and computer program for manufacturing an implant placement guide, and more particularly, to a system, method, and computer program for manufacturing an implant fixture placement guide using a ready-made guide tray.

Dental implant surgery involves placing an implant fixture in the alveolar bone. In order to properly place the implant fixture in the alveolar bone, a guiding device commonly called a guide stent or surgical guide is widely used. Guide currently used in the surgical field Stents are Korean Patent Registration No. 10-1473192 (Prior Document 1, Title of Invention: Manufacturing Method of Guide Stent for Implant, Publication Date: 2014.12.16.), Korean Patent Registration No. 10-1554157 (Prior Document 2, Oral Intraoral A reference marker for attachment and a method for manufacturing a guide stent for implant procedure using the same, publication date: 2015.09.21. 1, and referring to FIG. 1, a conventional guide stent manufacturing method is briefly described as follows. First, in dentistry, the operator acquires a 3D image of the inside of the oral cavity (periodontal tissue in the oral cavity) through a CT scan of the person to be treated, and acquires a 3D external shape image corresponding to the 3D image through an oral scan (s1) . Oral scan is performed by the operator inserting the scanner into the oral cavity of the person being treated. Since the scan must be performed along the inside of the oral cavity, distorted images frequently occur. It is necessary to check the shape of the gums or crown of the person to be treated. The 3D image of the inside of the person's oral cavity and the external shape image obtained in this way are image matched based on the characteristics or markers of the teeth included in each image, and through image matching A 3D treatment guide image is generated (s2). The operator establishes an implant operation plan using the 3D operation guide image (s3), and manufactures a stent body with a guide hole formed according to the operation guide image (s4). Generally, from the first step (s1) to the last step ( It takes about 2~3 days until s4), because each step is not all done by one subject. In particular, since the manufacturing of guide stents is done by guide stent manufacturers with precision processing facilities rather than by implant operators (dentists), guide stent manufacturers establish 3D surgical guide images or implant treatment plans to guide stents. It can only take a lot of time from manufacturing the stent to the operator receiving delivery of the guide stent. Even if the dentist is equipped with equipment such as a 3D printer, 3D printing takes a lot of time, so the person receiving the treatment has to endure the inconvenience of cost and time. In addition, the external shape image obtained through oral scanning is distorted. Since this is unavoidable, there is a problem in that the guide stent made through image matching does not exactly fit the oral structure of the person to be treated frequently.

The present invention is intended to solve the above-mentioned problems, and an object of the present invention is to remarkably improve the convenience of the recipient by dramatically shortening the guide stent manufacturing time. In addition, the present invention manufactures an implant placement guide using a ready-made tray. Another object of the present invention is to enable each performer participating in the production of an implant placement guide to easily generate profits and to distribute profits in a fair manner by providing a system for implant placement guides. In addition, the present invention is directed to designing and Another object of the present invention is to provide a guide manufacturing system, method, and computer program capable of facilitating modification. In addition, the present invention enables the manufacture of an implant placement guide without matching a three-dimensional image of the oral cavity with an external shape image. Another object of the present invention is to provide a method and system for manufacturing an implant placement guide that can provide a guide that fits the inside of a person's oral cavity without error.

In order to achieve this object, the present invention provides an implant placement guide manufacturing system, in which a guide tray filled with impression material is inserted into the oral cavity of a person to be operated on, and transmits a CT imaged 3D image to a server, and uses the 3D image to A dental terminal for receiving the created implant placement guide processing file, a management server for transmitting a design request signal to one or more pre-registered planner terminals upon receiving the 3D image from the dental terminal, and the design request signal from the management server. When is received, a planner terminal transmits whether the design request signal is accepted to the management server, and when the 3D image is received from the management server, receives implant design information corresponding thereto and transmits it to the management server, , The guide tray is characterized in that it includes one or more markers for identifying the type of the guide tray.

According to the present invention as described above, the manufacturing time of the implant placement guide is drastically reduced, and the user's convenience is remarkably improved. In addition, according to the present invention, it is easy for each performer involved in manufacturing the implant placement guide. In addition, according to the present invention, it is easy to design and modify implant placement guides. In addition, according to the present invention, the 3D image of the inside of the oral cavity and the external shape image are not matched. Since it is possible to manufacture an implant placement guide without error, it is possible to provide the person to be treated with a guide that fits inside the oral cavity of the person to be treated without error.

1 is a flow chart for explaining a conventional manufacturing method of a guide stent for implantation;
2 is a view for explaining an implant placement guide manufacturing system according to an embodiment of the present invention;
3 is a view for explaining an implant placement guide manufacturing system according to another embodiment of the present invention;
4 is a flowchart for explaining a method for manufacturing an implant placement guide according to an embodiment of the present invention;
5 is a flowchart for explaining a method of manufacturing an implant placement guide according to an embodiment of the present invention;
6 is a flowchart for explaining a method for manufacturing an implant placement guide according to an embodiment of the present invention;
7 is a view for explaining an implant placement guide manufacturing system according to an embodiment of the present invention;
8 is a flowchart for explaining a method of manufacturing an implant placement guide according to an embodiment of the present invention;
9 is a flowchart illustrating a method of manufacturing an implant placement guide for a processing machine according to an embodiment of the present invention.
10 is a diagram illustrating an implant placement guide manufacturing system according to an embodiment of the present invention.

The above objects, features and advantages will be described later in detail with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention belongs will be able to easily implement the technical spirit of the present invention. In describing the present invention, if it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar elements, and all combinations described in the specification and claims may be combined in any manner. And unless otherwise specified, it should be understood that references to the singular may include one or more, and references to the singular may also include plural. 2 is a diagram illustrating an implant placement guide manufacturing system according to an embodiment of the present invention. A dental terminal 400, an implant placement guide manufacturing management server 100 (hereinafter , Referred to as the 'management server 100'), a planner terminal 200, and may further include a design review terminal 300 and an implant placement guide processing machine 500. The dental terminal 400 is a dentist The terminal included in the device may be an electronic device such as a PC, a tablet, or a smartphone in which an application program for executing the method for manufacturing an implant placement guide according to an embodiment of the present invention is installed. Furthermore, if the method for manufacturing an implant placement guide according to an embodiment of the present invention is implemented as a web, it may be an electronic device that can be connected to the web. A 3D image taken by CT is transmitted to the management server 100, and a file for processing an implant placement guide is received from the management server 100. Tray) and its shape may be similar, but it is a ready-made guide tray in which the shape of the user's teeth is impressed, i) used to match the image of the guide tray with a three-dimensional image, ii) used to identify the type of guide tray, iii) It is different in that it includes a marker used to identify whether or not sleeve mounting is required. The guide tray according to an embodiment of the present invention may include one or more markers that perform the above-described functions, and preferably, the marker can be formed of three or more. The marker may be a radiopaque material, and thus may be displayed on a 3D image obtained through a CT scan. The marker may be formed on a flat surface of the body that accommodates the impression material in the guide tray. In this case, the marker is a criterion for the planner or operator to identify the guide tray in the 3D image and to match the 3D image with the image of the guide tray. becomes In addition, the marker can be a standard for designing the location, depth, direction, etc. of the implant fixture to be placed. The operator fills the guide tray with impression material, inserts the tray into the oral cavity of the person to be operated on, and places it on the area to be implanted. A CT scan is performed while wearing it. The 3D image of the inside of the oral cavity acquired through CT scanning is information on internal tissues such as the crown (the upper side of the tooth exposed outside the gum), the root (the lower side of the tooth hidden within the gum as a part combined with the alveolar bone), and the alveolar bone. It includes a marker image of the guide tray. The 3D image does not accurately provide information on the gums, and conventionally, in order to solve this problem, a 3D external shape image was obtained through an oral scan, and the 3D image of the inside of the oral cavity and the external shape image were image matched. However, since an oral scan is unnecessary according to an embodiment of the present invention, it is sufficient for the dental terminal 400 to transmit the CT-photographed 3D image to the management server. Therefore, the process of acquiring oral condition information of the person to be operated on for implant surgery is significantly shortened, which leads to the effect of reducing the operation time and cost. A managing computing device, which may be a web server or a cloud server. Upon receiving the 3D image from the dental terminal, the management server 100 transmits a design request signal to one or more pre-registered planner terminals, and receives implant design information from the planner terminal that has accepted the design request signal. A file for processing the insertion guide can be created. The design request signal may be a text message (SMS) or a push notification transmitted through an application program installed in the planner terminal 200. In the present specification, implant design information is displayed on a 3D image. As the information on which the implant procedure plan is established, at least one of the size of the fixture, the type of fixture, the position of fixture implantation, the depth of fixture implantation, whether bone has been transplanted, whether or not the maxillary sinus transplant has been performed, whether gums have been transplanted, and the order of tools used can include According to the present invention, the implant design information can be generated by a user using each terminal in the planner terminal 200, the design review terminal 300, or the dental terminal 400, and the implant design information of the present invention is implant It can be created, copied, transmitted, and stored in the form of a design information file (STL file and/or PDF file). The operation of the management server 100 will be described later in detail with reference to FIG. 3. One embodiment of the present invention The implant placement guide manufacturing system 10 according to the example may include a planner terminal 200 . The planner terminal 200 may be a terminal of a user who has already been authenticated as having implant design qualifications, or a user terminal who has been authenticated as having both implant design qualifications and doctor qualifications. When the design request signal is received from the management server, the planner terminal 200 transmits whether or not to accept the design request signal to the management server, and when a 3D image is received from the management server, receives implant design information corresponding to the received implant design information to the management server. The implant placement guide manufacturing system 10 of the present invention may further include a design review terminal 300 . The design review terminal 300 is a terminal of a user certified as having a doctor's qualification, and in the case where the user of the planner terminal 200 is a user's terminal certified as having both an implant design qualification and a doctor's qualification, the system 10 ) may not be included. When the design review terminal 300 receives a review request signal from the management server, it transmits whether or not to accept the review request signal to the management server, and when implant design information is received from the management server, the corresponding review result is received and managed. The acceptance signal may be transmitted to the server. The transmission of the acceptance signal is an act of the user touching or clicking a link in the message (SMS) displayed through the terminals 200 and 300, and the acceptance displayed on the web page provided through the web server 100. It can be done through an act of touching or clicking a button or link, or an act of touching or clicking an acceptance button of an application installed on the terminal (200, 300), and the method of transmitting acceptance to the server 100 is not limited thereto. The implant placement guide manufacturing system 10 of the present invention may further include an implant placement guide processing machine 500 (hereinafter referred to as 'processing machine 500' for convenience of explanation). The processing machine 500 according to an embodiment of the present invention is provided in a dental office that transmits a 3D image, and when a file for processing an implant placement guide is received from a management server or a dental terminal, the processing machine 500 uses the file for processing an implant placement guide to guide the tray. Locations of jigs and guide holes corresponding to the type of the jigs may be identified, and guide holes may be drilled in the guide tray using the identified jigs. The file for processing the guide for implant placement includes an image of the guide tray showing the location of the guide hole. The file for processing may or may not include implant design information on the guide tray image. Furthermore, a sleeve made of metal may or may not be mounted on the guide hole. In the case of mounting, the file for processing may include information on the location of the sleeve and the region to be deleted due to the mounting of the sleeve. 500, the operator (dental terminal) acquires the 3D image of the inside of the patient's oral cavity and transmits it to the management server to receive the file for processing the implant placement guide within a few minutes to 1-2 hours. In addition, when the file for processing the implant placement guide is transmitted to the processing machine 500 - and the file for processing the implant placement guide is directly transmitted to the processing machine 500, even that is unnecessary. - When the guide tray with the impression of the person to be treated is mounted on the processing machine 500, the processing machine 500 automatically identifies the location of the guide tray, guide hole, and necessary jig in the already created guide tray, and only needs to drill a guide hole. , you can get an implant placement guide in minutes. In addition, the implant placement guide according to an embodiment of the present invention is characterized in that the impression material is hardened after filling the impression material, inserting it into the teeth and gums of the person to be treated, and then hardening the impression material, and the shape of the person's teeth is raised, Therefore, it is seated without error on the teeth and gums of the person being treated. Therefore, not only is the implant procedure very easy, but there is no problem that the implant placement guide does not fit into the inside of the user's oral cavity, so correction is unnecessary and the satisfaction of the recipient increases. In one embodiment of the present invention, the implant placement guide A file for processing can be recognized by the processing machine 500 (or a milling machine), and may include an NC file that can be recognized by a CAM program, which is a processing machine driving program. The operating method of the guide manufacturing system 100 will be described. Example 1: Case where the system is composed of a dental terminal, a planner terminal, and a management server. This is an example of a case in which all Since the final confirmation for the implant procedure must be performed by a doctor, in this embodiment, it is assumed that the user of the planner terminal has a doctor's qualification. Referring to FIG. 4, the dental terminal is the guide tray of the present invention. Obtains a three-dimensional image obtained through CT imaging in a state in which is inserted into the oral cavity (S100). This means that the dental terminal receives a 3D image acquired through CT imaging from the imaging device. Next, the dental terminal may transmit the 3D image to the management server. Transmission to the management server includes uploading the 3D image. In the 3D image transmitted from the dental terminal to the management server, identification information of the dental terminal (dental code, dentist name, operator name, etc.) and patient information (operator name, age, gender, other personal information required for implant treatment, etc.) When the management server receives the 3D image (S200), that is, when the 3D image and other information are uploaded, it may transmit a design request signal to one or more pre-registered planner terminals (S300). As described above, transmission of the design request signal may be implemented by notifying the planner terminal of the fact of upload. The planner terminal is a terminal used by planners with implant design qualifications and doctor qualifications. It may be a terminal device in which an application program supporting a method of manufacturing an implant placement guide is installed. Through the application program or the web, planners can register planner information in advance in the management server, and at the time of registration, user information of the planner terminal (planner's name, planner's qualifications, planner activity history, etc.) is transmitted to the management server. can transmit The management server may grant different statuses to planners after confirming qualifications possessed by the planners. For example, planners with only implant design qualifications are given Level A, and planners with both implant design qualifications and doctor qualifications are given Level S. That is, planners can be classified into one or more groups according to the skills possessed, and the criteria can vary according to the setting of the administrator. As another example, the management server can classify planners according to the planner's holding history. The planner can be classified according to the feedback (star rating or review) of the dental terminal. The planner can access the management server regardless of the terminal using the ID and password registered in advance, and designate the time he/she wants. In this way, the design request signal may be received, and whether to receive or reject the design request signal may be set. [0040] When the design request signal is received in step 300, the planner may determine whether to accept the design request signal and input the result to the terminal. When the planner inputs a selection input for accepting the design request signal to the planner terminal, the planner terminal may transmit a signal indicating that the design request signal has been accepted to the management server (S400). The management server receives the acceptance of the design request signal. If so, the 3D image may be transmitted to the planner terminal accepting the design request signal (S500). Acceptance of the design request signal and transmission of the corresponding 3D image signify the conclusion of the contract between the management server and the planner, and in step 500, the planner connects to the management server using the planner terminal, dicom file). If acceptance of the design request signal is received from a plurality of planner terminals, the management server may select one or a plurality of planner terminals according to a predetermined criterion. For example, the management server may select a planner terminal based on the order in which a signal accepting the design request signal arrives at the management server, and uses pre-registered planner information to select a planner terminal with the least or most implant design history. you can also choose The criterion for selecting a planner terminal may vary according to the administrator's setting, and whether to select one planner terminal or multiple planner terminals may also vary according to the manager's setting. Implant design information is generated based on the dimensional image (S600). Implant design information is the information on which the implant procedure plan is established on the 3D image, such as the size of the fixture, the type of fixture, the position of fixture implantation, the depth of fixture implantation, bone transplantation, maxillary sinus transplantation, and gum transplantation. , at least one of the order of tools used. Information such as the size of the fixture and the type of fixture may be input to the planner terminal through an input device such as a touch screen, keyboard, mouse, or touch pad provided or connected to the planner terminal, and the planner terminal uses the input information. Thus, implant design information can be created. The implant design information of the present invention can be generated, copied, transmitted, and stored in the form of an implant design information file (STL file and/or PDF file). The planner terminal transmits the generated implant design information to the management server (S700 ). Transmission of the implant design information to the management server includes an operation of the planner terminal uploading the implant design information (STL file and/or PDF file) to the web server or cloud server corresponding to the management server. However, the management server may check the classification information of the planner terminal that has transmitted the implant design information to the management server. If it is confirmed that the planner terminal is a planner terminal having both implant design qualifications and doctor qualifications, the management server may generate a file for processing an implant placement guide using the implant design information (S800). In step 800, the implant design information is It may be a job of converting a file into a file in a format that the processor can recognize. For example, in step 800, the management server 100 may convert the implant design information into an NC file that the processing machine 500 can recognize. Implant design information can be a web provided by the management server or a file in a format supported by an application program (eg CAD file, STL (Stereo Lithography) file), and implant design information can be a file for processing an implant placement guide (eg NC file). ) may be an inherent authority of the management server. The management server may generate a file for processing an implant placement guide using a CAM program that is executed only on the web or in the cloud. As another embodiment, the implant design information may be encrypted when generating the implant design information so that the implant design information is converted into a file in a format processable by a processing machine only by the management server. Alternatively, the implant design information may be a file that can be generated only by a web or application program provided by the management server of the present invention. Furthermore, a file for processing an implant placement guide according to an embodiment of the present invention may be a file having a format that can be executed only by a pre-designated processing machine. Conversion of implant design information into a file for processing an implant placement guide is an inherent authority of the management server. This is to build a profit model based on the fact that the management server creates (or outputs) the file for processing the implant placement guide. For example, when the file for processing the guide for implant placement is generated (S800), the management server creates the file for processing the guide. It is possible to check whether payment information (card information or account information, etc.) corresponding to the dentist (terminal) or processing machine requested is registered (S830). If the dentist has registered card information or account information, the dentist may be notified of the creation of a file for guide processing (S850), and the file for processing may be transmitted (S900). Step 900 includes a method for the dental terminal to access the web server 100 and download a file. After the file is transmitted, the cost corresponding to the file transmission for processing may be paid using the payment information (S1000). Step 1000 may be performed before steps 850 and 900. As a result of the determination in step 830, if the payment information of the dentist who requested the file for guide processing is not registered in the management server 100, the management server 100 sends the corresponding dentist Connection of the terminal to the server 100 may be blocked. For example, if the management server is a web server, access to the web server of dental terminals for which payment information is not registered may be blocked or permission may not be granted, thereby limiting download of files for guide processing. , The management server transmits the file for processing the implant placement guide to the dental terminal or processing machine (S900), counts the number of outputs or transmissions of the file for processing the implant placement guide, and charges the dental terminal for the design cost for the number of times (S1000 ). In an embodiment different from that shown in the drawing, the service fee may be charged before the step 800 of generating the file for processing the implant placement guide or the step 900 of transmitting the file for processing the implant placement guide, and the service amount corresponding to the charge from the dental terminal. When this deposit or payment is completed using payment information, it is also possible to perform step 800 or step 900. The payment information may be payment information pre-registered in the server, or may be received and used from the dental terminal. In this case, the web server or the cloud server may provide a payment information input interface for receiving payment information to the dental terminal. The management server, when the service amount is deposited, transfers the remaining amount excluding the preset fee to the planner terminal that designed the implant. 1 (S1100) Embodiment 2: When the system is composed of a dental terminal, a planner terminal, a design review terminal, and a management server As shown in FIG. 2, the dental terminal 400, An embodiment in which a system is configured with the planner terminal 200 , the design review terminal 300 , and the management server 100 will be described with reference to FIG. 5 . In this embodiment, it is assumed that the planner terminal is a terminal of a user authenticated as possessing only implant design qualifications, and the design review terminal is a user terminal certified as having doctor qualifications. Some steps omitted in FIG. 5 may refer to FIG. 4 (assuming that the planner terminal of FIG. 5 is the planner terminal 1 of FIG. 4). In the case of implant design information generated by a planner having only implant design qualifications, the doctor qualification It needs to be verified by the possessing user. Therefore, if the planner terminal accepting the design request signal in response to the design request signal transmission in step 300 is the planner terminal certified as having only the implant design qualification, the management server generates the generated A step of reviewing the implant design information may be additionally performed. Referring back to step 600, the management server may receive the implant design information from the planner terminal and transmit a review request signal to one or more pre-registered design review terminals. Yes (S710). When a review request signal acceptance is transmitted from one of the plurality of design review terminals that have received the review request signal (S720), the management server may transmit implant design information to the design review terminal that has accepted the review request signal (S730). ). Steps 720 to 730 of selecting a terminal for design review may be performed in a method similar to the embodiment described in steps 300 to 400 of FIG. 4 . That is, acceptance of the review request signal and transmission of implant design information can be understood as signifying the conclusion of a contract between the management server and the design review terminal. The design review terminal may transmit the review result to the management server (S740). . The review result may include correction opinions and corrections for the implant design information, and may include a confirmation opinion that the implant design was properly performed. The management server checks the review result (S750), and if the review result includes a revision opinion, it may transmit the review result to the planner terminal (S753). The implant design information may be modified using (S755), but if a planner exists in the center having a management server, the management server may internally reflect the review result and modify the implant design information. Alternatively, the management server may self-reflect the review opinion and modify the implant design information by using a machine learning framework learned from a large amount of data. The modified implant design information is transmitted to the management server again (S760). , The management server forwards it to the design review terminal again (S765), so that correction and review can be repeated until correction is unnecessary. If there is no modification as a result of the review, the management server transfers the implant design information to the dentist It can be transmitted to the terminal (S770), and when the implant design information is approved by the dental terminal (S780), a file for processing the implant placement guide can be created (S800). For reference, steps 770 and 780 are applicable before step 800 is executed even in the embodiment of FIG. 4 . That is, unnecessary file conversion can be minimized by generating a file for processing an implant placement guide after receiving confirmation of implant design information from the dental terminal. By transmitting the implant design information and the remote access address that can share and modify the 3D image in real time with the planner terminal that generated the information, real-time modification and confirmation between the planner terminal and the design review terminal are possible without steps 740 to 760. can do. Such an embodiment is shown in FIG. 6 . Referring to FIG. 6 , the design review terminal receiving the remote access address remotely accesses the planner terminal (S735) to share and modify implant design information (S737). In this case, the implant design information is provided through the management server. Since there is no need to send and receive, the modification and confirmation steps can be greatly shortened. Sharing and modification of implant design information through remote access may be performed through the implant placement guide production application or the web according to the present invention, but may also be performed through other application programs that support remote access. An implant placement guide system according to this embodiment is additionally shown in FIG. 10. FIG. 6 shows an embodiment of a case in which a dental terminal transmits a modification request (S790). When the dental terminal returns a modification request to the received implant design information instead of an approval reply as in step 780 shown in FIG. 5 (S790), the management server transmits the modification request to the planner terminal (S793), Implant design information reflecting the modification request may be received and transmitted to the dental terminal (S797), and steps 793 to 797 may be repeated until approval is received from the dental terminal. As in Example 4, a service fee may be requested from the dental terminal before or after generating a file for processing an implant placement guide (S1000), a predetermined design cost is transferred to an account linked to the planner terminal, and a terminal for design review. A preset design review cost may be transferred to an account linked to (S1100). Embodiment 3: When a system is configured with a terminal and a management server The embodiments shown in FIGS. 7 to 8 include i) a management server. In case the entire process of implant procedure is performed in one center (in this case, the terminal can be understood as a computing device used in the center, and the management server means a server provided in the center), ii) Dentistry equipped with a dental terminal This is an example of a case in which the system is composed of a center having a management server and a terminal (in this case, a terminal may be understood to mean a dental terminal, and a management server refers to a server (web server or cloud server) provided in the center). The terminal may obtain a three-dimensional image of the oral cavity of the person to be treated through CT imaging in a state where the guide tray is inserted into the oral cavity (S10). Acquisition of the 3D image includes receiving the 3D image from the CT imaging device and receiving the 3D image through a wired or wireless communication network. The terminal may receive implant design information from the terminal user (S20). For example, a terminal user may draw an implant procedure plan on a 3D image through an input means connected to the terminal, and may include the size of the fixture, type of fixture, fixture placement location, fixture placement depth, and bone grafting. It is also possible to describe whether or not, whether or not there was a maxillary sinus transplant, whether or not a gum was transplanted, and the order of tools used. As described above, the implant design information may be generated in the form of an STL file, and may include an STL file generated through a CAD program and a PDF file describing an operation method. When the implant design information is input, the terminal designs the implant. According to the information, the position of the guide hole can be displayed on the image of the guide tray. In addition, a file for processing an implant placement guide including an image of a guide tray marked with a guide hole position can be created (S30). Creation of a file for guide processing may be performed through file conversion of converting an STL file, which is an implant design information file, into an NC file. This file conversion can be done through a CAM program running on a web or cloud server. In this case, the terminal may convert the file by uploading the file for guide processing to a web or cloud server and downloading the converted file when the file is converted. As another embodiment, the terminal may be directly converted to a file using a program installed in the terminal. The generated file for processing the implant placement guide is transmitted to the processing machine (S40), and the processing machine uses the received file for processing to convert the implant placement guide. Process (S50). Processing of the implant placement guide is possible with a simple operation of drilling a guide hole in the guide tray inserted into the user's oral cavity, and processing time can be greatly reduced because 3D printing or sophisticated work is not required. See FIG. 9 for step 50. More specifically, the processing machine can identify the guide tray using the number of guide tray markers included in the implant placement guide processing file (shown in the 3D image), the shape of the markers, and the angle formed by the plurality of markers. Yes (S51). The guide tray has various shapes and sizes corresponding to its purpose and oral structure of a person to be treated. The guide tray used in the present invention may have a unique identification code for each type and may have unique marker information. That is, the number and shape of the markers appearing in the 3D image, and the angles and shapes formed by the plurality of markers can be matched with each unique identification number. The tray library and the Z library can be searched (S53). The tray library is a database including external information and identification information of various guide trays, and the jig library is a database including external information and identification information of processing machine jigs suitable for use for each guide tray. The processing machine can drill a guide hole using a jig that matches the identified guide tray (S55). After that, the processing details from the terminal can be transmitted to the management server (S60), and the management server records the processing details and (S70), and accordingly, a cost may be charged to the dental terminal (S80). However, steps 60 through 80 are additional and can be omitted. Lastly, a method for manufacturing an implant placement guide according to an embodiment of the present invention will be summarized and described. In the state of being inserted into the oral cavity, a 3D image of the patient's oral cavity is obtained through CT imaging, and implant design information is input on the 3D image. Next, the electronic device receives marker information of the guide tray included in the 3D image. The image of the guide tray is matched to the 3D image using the 3D image. The electronic device displays the position of the guide hole on the image of the guide tray according to the implant design information, and implant placement is performed using the image of the guide tray on which the position of the guide hole is displayed. Creates a file for guide processing. The electronic device creates a guide hole in the guide tray using a file for processing the implant placement guide, and the guide tray is characterized in that the tooth shape of the person to be operated is raised. The electronic device displays the position of the guide hole, implant design information A guide hole image can be created on the guide tray image based on the vertical axis of the implant fixture included in the guide hole, and a deletion area for jig insertion can be displayed centered on the guide hole. Furthermore, the electronic device can display the implant placement guide processing file. Costs corresponding to the number of times of generation can be remitted to a preset server account. Some embodiments omitted in this specification are equally applicable when the implementing entity is the same. In addition, the above-described present invention relates to technology to which the present invention belongs. Various substitutions, modifications, and changes are possible to those skilled in the art without departing from the technical spirit of the present invention, so it is not limited by the above-described embodiments and the accompanying drawings.

100: Implant placement guide production management server (management server)
200: planner terminal
300: terminal for design review
400: dental terminal
500: processing machine

Claims (24)

A method for managing the production of an implant placement guide by an implant placement guide production management server, comprising: a step of receiving, from a dental terminal, a three-dimensional image of an oral cavity captured by CT in a state in which a guide tray filled with an impression material is inserted into the oral cavity of a person to be operated on;
Step b of transmitting a design request signal to one or more pre-registered planner terminals;
step c of transmitting the 3D image to a first planner terminal that has accepted the design request signal;
step d of receiving implant design information generated based on the 3D image from the first planner terminal;
Step e of generating a file for processing an implant placement guide in which the position of a guide hole is indicated on the image of the guide tray by using the implant design information; And a step f of transmitting, wherein the guide tray includes one or more markers for matching the image of the guide tray with the three-dimensional image, and the implant placement guide manufacturing management characterized in that the tooth shape of the person to be treated is raised. method. According to claim 1,
The step e is: matching the image of the guide tray with the 3D image using the marker; displaying the position of the guide hole on the image of the guide tray according to the implant design information; and generating a file for processing the implant placement guide using the displayed image of the guide tray. According to claim 1,
If the first planner terminal is a terminal of a user certified as having only implant design qualifications, after the step d, transmitting a review request signal to one or more pre-registered design review terminals; 1 transmitting the implant design information to a design review terminal; receiving a review result of the implant design information from the first design review terminal; and transmitting the review result according to the review result to the first planner terminal. Retransmitting to or transmitting the implant design information to the dental terminal; When approval for the implant design information is received from the dental terminal, further comprising the step of performing step e, wherein the design review terminal is a doctor A manufacturing and management method for an implant placement guide, which is a terminal of a user certified as having qualifications. According to claim 3,
The transmitting of the implant design information includes transmitting implant design information including a remote access address capable of sharing and modifying the 3D image with the first planner terminal in real time to the first design review terminal. How to manufacture and manage implant placement guides. According to claim 1,
The step f may include determining whether payment information corresponding to the dental terminal or the processing machine is registered;
and transmitting the file for processing the implant placement guide to the dental terminal or the processing machine if the payment information is registered. The method of claim 1, wherein step e
Transmitting the implant design information to the dental terminal;
and generating a file for processing the implant placement guide when an approval for the implant design information is received from the dental terminal. According to claim 1,
The step e may include transmitting the implant design information to the dental terminal;
transmitting the modification request to the first planner terminal when a modification request for the implant design information is received from the dental terminal;
receiving first implant design information reflecting the modification request from the first planner terminal;
Transmitting the first implant design information to the dental terminal;
and generating a file for processing the implant placement guide when an approval for the implant design information is received from the dental terminal. According to claim 1,
The implant design information may further include at least one of a size of a fixture, a type of fixture, a fixture placement position, a fixture implantation depth, bone transplantation, maxillary sinus transplantation, gum transplantation, and an order of tools to be used. How to manage production. According to claim 1,
The method of manufacturing and managing an implant placement guide, further comprising: paying a predetermined service amount using payment information corresponding to the dental terminal; performing step e or step f when the payment is completed. According to claim 9,
The method of manufacturing and managing an implant placement guide, further comprising remitting an amount remaining after excluding a predetermined fee from the service amount to an account associated with the first planner terminal. According to claim 3,
The implant placement guide production management method further comprising the step of remitting a preset design cost to an account associated with the first planner terminal and remitting a preset design review cost to an account associated with the first design review terminal. The method of claim 1, wherein the marker is made of a radiopaque material. The method of claim 1, wherein the number of markers is three or more. The method of claim 1, wherein the implant design information includes a stereo lithography (STL) format file. An implant placement guide manufacturing management program stored in a computer readable medium in order to execute any one of the methods of claims 1 to 14. A method for manufacturing an implant placement guide by a planner terminal, comprising: receiving a design request signal from a management server; receiving a user's acceptance or non-acceptance of the design request signal and transmitting the result to the management server; Receiving a 3D intraoral image obtained by CT imaging in a state in which a guide tray filled with a guide tray is inserted into the oral cavity of a person to be treated; Receiving implant design information corresponding to the 3D image from a user; Managing the implant design information And transmitting to a server, characterized in that the guide tray includes one or more markers for matching the image of the guide tray and the three-dimensional image, and the tooth shape of the person to be treated is raised. The guide processing file includes an image of the guide tray in which the location of the guide hole is indicated. According to claim 16,
The method of manufacturing an implant placement guide of a planner terminal further comprising requesting a predetermined design price from the management server in response to the transmission of the implant design information. An implant placement guide production program of the planner terminal stored in a computer readable medium in order to execute any one of the methods of claims 16 to 17. In the method for manufacturing an implant placement guide by a dental terminal,
Obtaining a 3D image of the oral cavity obtained by CT imaging in a state where a guide tray filled with impression material is inserted into the oral cavity of a person to be operated on; Transmitting the 3D image to a management server; Based on the 3D image from the management server Receiving generated implant design information; Receiving an input of whether or not to approve the implant design information from a user; Transmitting the approval or not to the management server; Generated using the implant design information from the management server. Receiving a file for processing an implant placement guide, wherein the guide tray includes one or more markers for matching the image of the guide tray and the three-dimensional image, and the tooth shape of the person to be treated is raised and wherein the file for processing the implant placement guide includes an image of the guide tray in which the location of the guide hole is displayed. The method of claim 19, wherein the receiving of the file for processing the implant placement guide comprises: remitting a predetermined service amount to an account linked to the management server; the file for processing the implant placement guide from the management server in response to the remittance. A method of manufacturing an implant placement guide of a dental terminal comprising the step of receiving a. An implant placement guide production program of a dental terminal stored in a computer readable medium in order to execute any one of the methods of claims 19 to 20. In the implant placement guide manufacturing system, in a state in which a guide tray filled with an impression material is inserted into the oral cavity of a person to be operated on, a 3D image of the oral cavity captured by CT is transmitted to a management server, and a dental implant placement guide processing file is received from the management server. Terminal; Upon receiving the 3D image from the dental terminal, a design request signal is transmitted to one or more pre-registered planner terminals, and when implant design information is received from the planner terminal that has accepted the design request signal, implant placement is performed using the same. A management server that generates a file for guide processing; When the design request signal is received from the management server, whether or not to accept the design request signal is transmitted to the management server, and when the three-dimensional image is received from the management server, the corresponding It includes a planner terminal for receiving implant design information and transmitting it to the management server, and the guide tray includes one or more markers for matching the image of the guide tray and the three-dimensional image, and the tooth shape of the person to be treated is raised. , The implant design information includes positional information of guide holes formed in the guide tray. The method of claim 22, When receiving a review request signal from the management server, whether or not to accept the review request signal is transmitted to the management server, and when the implant design information is received from the management server, a review result corresponding thereto is transmitted. The implant placement guide manufacturing system further comprising a design review terminal for receiving an input and transmitting it to the management server. 23 . The method of claim 22 , which is provided in the dental office that transmits the 3D image, and when the file for processing the implant placement guide is received from the management server or the dental terminal, the guide tray is provided using the file for processing the implant placement guide. The implant placement guide manufacturing system further comprising an implant placement guide processing machine for drilling the guide hole.

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